EP1059980B1

EP1059980B1 - Antimicrobial filter cartridge

Info

Publication number: EP1059980B1
Application number: EP98908818A
Authority: EP
Inventors: Gilbert Patrick; Arvind S. Patil
Original assignee: Microban Products Co
Current assignee: Microban Products Co
Priority date: 1995-12-15
Filing date: 1998-03-02
Publication date: 2004-05-12
Anticipated expiration: 2018-03-02
Also published as: EP1059980A1; US5762797A; AU6675998A; CA2200292A1; DE69823881T2; DE69823881D1; CN1150959C; ES2221157T3; CA2200292C; EP1059980A4; CN1301189A; WO1999044712A1; ATE266455T1

Abstract

An antimicrobial filter cartridge having a perforated core member wrapped with a microporous membrane, which is overwrapped with a spiral wrapping of an antimicrobial agent impregnated yarn. The spiral wrapping is covered with a criss-cross wrapping of yarn. The filter cartridge is sized so as to fit tightly into a cartridge housing of a fluid filtration system. Fluid passing through the cartridge housing will be filtered by the filter cartridge to remove microorganisms from the water and which prevents the growth of microorganisms on the filter media.

Description

FIELD OF THE INVENTION

This invention relates generally to filters for the purification of liquids. In particular, the present invention relates to an antimicrobial filter cartridge for a filtration system for removing microorganisms from water and which is formed from layers of yarns and nonwoven webs or mats wound or wrapped in varying patterns and treated with an antimicrobial agent to enable the filter cartridge to trap and remove low micron organic contaminant particles and prevent the growth of the trapped microorganisms on the filter cartridge media to significantly reduce the level of contaminants and bacteria within the water flowing through the filtration system.

BACKGROUND OF THE INVENTION

In recent years, the public has been increasingly aware of the deteriorating quality of our nation's water supply. Municipalities are requesting the EPA to lower the standards of tap water to a much lower quality. Medical patients with low immunity are requested not to drink tap water. The major part of the contamination of the drinking water is bacterial in nature.
All over the world, countries with increasing populations are concerned that the water quality has deteriorated to an all time low. However, many known solutions that exist to purify water are too expensive or are not feasible in certain locations.
Reverse osmosis systems are one of the most common solutions for the improvement of water quality. Generally, these systems use a sediment removal filter in conjunction with activated carbon and bacteriostatic membrane coated with oxides and halide of silver, as described in detail by Nishino in U.S. Patent 3,872,013, placed between the filter and the water outlet. The membrane will prevent certain bacteria from leaving the filter and will retard their growth on the surface of the membrane, but will not check their growth on the activated carbon and their ability to multiply and produce toxins. This also holds true for other mechanical filters such as ceramic filter cartridges that filter out bacteria of about 1 µm in size, but are ineffective in retarding bacteria growth as the bacteria are collected on the surface of the filter.
Another type of biocidal reverse osmosis system is described in detail by Medlin in U.S. Patent 5,269,919. Medlin describes how a polyiodide resin releases iodide upon contact with bacteria and viral organisms and uses granular metal alloys and activated carbon to remove iodides released in the water. If not removed, these iodides would be harmful internally to human beings. The EPA "Policy on Iodine Disinfection", initially developed in 1973 and reaffirmed in 1982, is that iodine disinfection is for short-term only, whenever iodine-containing species remain in the drinking water.
In view of the foregoing, it would appear that present water purification systems become a breeding ground for bacteria and toxins or would subject users to the possibility of trace metals such as silver and copper, and other contaminants not filtered out of the water.
EP 0989898 A, which is a prior art document in accordance with Article 54(3)(4) EPC describes an antimicrobial filter cartridge having a perforated core member wrapped with a first microporous membrane, which is in turn overwrapped with a second and a third microporous membrane. The membranes are covered with a crisscrossed wrapping of antimicrobial treated yarn. The filter cartridge is sized to fit tightly into a cartridge housing of a fluid filtration system.
JP-A-01274814 describes a filter for purification which is made of a filter medium with an adhered antibacterial agent. The filter medium is produced by winding a copper wire or a fiber with adhered copper sulfate and a fiber of PP or the like around a water-permeable cylindrical core material so as to leave voids.
It is the object of the present invention to provide a water filter cartridge to filter microscopic organisms and prevent their growth within the filter media, without releasing life harming biocides that have to be further filtered out.
This object is achieved by a cartridge according to claim 1.
Briefly described, the present invention comprises a filter cartridge for a water filtration system for safely and effectively filtering microorganisms from drinking water and prevents the further growth of the microorganisms trapped by the filter. The filter cartridge includes an inner tubular-shaped perforated core of a metal, plastic or ceramic material, or formed from activated carbon. The core is covered with a microporous membrane having nominal pores of approximately 0.45 µm to 0.10 µm. The membrane is tightly wrapped around the core, and preferably is slightly wider than the length of the core so as to overlap the two opposing ends of the core.
A yarn or nonwoven material that has been impregnated or otherwise treated with an antimicrobial agent is typically, spirally wound about the membrane so that there are no spaces between the turns or layers of the yarn and thus there are no voids between the yarn and the microporous membrane, forming a primary spiral yarn layer. Thereafter, another layer of antimicrobial yarn is then wrapped around the spiral layer in the standard criss-cross or diamond-wrap pattern, creating diamond-shaped openings through which water can travel.
In addition, the criss-cross layer can be covered with a second microporous membrane, also having a nominal pore size of 0.45 µm or less, followed by a second spiral layer of antimicrobial yarn and a second or outer criss-cross wound section of antimicrobial yarn. The outer criss-cross wound section is formed with sufficient thickness so that the filter cartridge can be tightly inserted into a cartridge housing, with minimal space between the filter cartridge and the housing walls. The ends of the membrane and yarn layers of the finished filter thereafter are sealed with an antimicrobial polymer or resin, forming end caps at the opposite ends of the filter, to ensure the fluids will pass through the entire filter before exiting the system.
The filter cartridge is installed within a housing for a filtration system connected to a water supply. As water flows into the housing, the water flows down and through the filter cartridge, and exits the housing through an outlet port. The filter cartridge of the present invention removes microorganisms and other impurities from water flowing through the cartridge. Large impurities generally are removed by the criss-cross layers or by the microporous membranes. Microorganisms retained by one of the membranes are forced into contact with the antimicrobial agent in the yarn because the tight spiral wrapping creates minimal void spaces between the yarn and the membrane. Thus, sufficient contact between the contaminants and the antimicrobial treated yarn to remove and treat the contaminants is achieved without requiring long contact times between the fluid flow and filter cartridge. An equally effective antimicrobial filter further can be obtained using a microporous ceramic candle or an extruded activated carbon core, without a microporous membrane as described above, so long as the effective nominal size of the pores of the ceramic candle or carbon core is less than 0.45 µm.
It is an advantage of the present invention that an antimicrobial filter cartridge is provided that overcomes the above-discussed and other deficiencies of the prior art by providing a filter cartridge that substantially completely filters microorganisms from water and prevents the growth of the microorganisms within the filter media.
It is another advantage of the present invention that an antimicrobial filter cartridge is provided that does not release harmful toxins into the water that must be removed from the water before the water can be safely consumed.
It is an advantage of the present invention that an antimicrobial filter cartridge is provided that can be used in presently available filtration system housings including those used in reverse osmosis systems that will inhibit the growth of microorganisms and subsequent toxin production and will protect the activated carbon filter commonly used in reverse osmosis filtering systems.
It is a further advantage of the present invention that an antimicrobial filter cartridge having very little dead space but with sufficient water flow is provided.
It is a still further advantage of the present invention that an antimicrobial filter cartridge is provided wherein nearly all of the water flowing into the filter cartridge comes into contact with an antimicrobial agent.
Other objects, features, and advantages of the present invention will become apparent to one with skill in the art upon examination of the drawings and the detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a side elevational view of a preferred embodiment of the present invention, with portions cut away.
Fig. 2 is a side elevational view of a second embodiment of the present invention, with portions cut away.
Fig. 3 is a cross-sectional view of one end of the embodiment of the filter cartridge of Fig. 2.
Fig. 4 is a side elevational view of the filter cartridge of the present invention.
Fig. 5 is an end view of the filter cartridge of the present invention with an end cap installed.
Fig. 6 is a schematic illustration of the filter cartridge of the present invention, showing the filter cartridge installed and used in an undersink filtration system.
Fig. 7 is a schematic illustration of the filter cartridge of the present invention showing the filter cartridge installed and used in a faucet filtration system.

DETAILED DESCRIPTION

Referring now to the drawings in which like numerals indicate like parts throughout the several views, Fig. 1 illustrates a preferred embodiment of a filter cartridge 10 constructed in accordance with the present invention. The filter cartridge 10 includes a hollow central perforated core 12 having open ends 13 and 14, and which can be formed from plastic, paper, or metal. Alternatively, the core can be manufactured of compressed activated carbon or ceramic candles, which are inherently perforated. The core is formed as a tube or cylinder approximately 12,7 - 76,2 cm (5 to 30 inches) in length and generally having a diameter of approximately 2,54 - 5,08 cm (1 to 2 inches), although larger or smaller diameters can be used if necessary. A series of pores or perforations 16 are formed through the core along its length.
A first microporous membrane 17 is wrapped tightly around the core so as to cover it completely. Preferably, the membrane 17 is a thin film having a width slightly greater than the length of the core 12 so that the membrane overlaps each of the open ends 13 and 14 of the core by approximately 0,3175 cm (0.125 inches). The microporous membrane has a series of pores of nominal size of about between approximately 5.0 µm to 0.10 µm, preferably 0.45 µm to 0.10 µm or less, so that it will effectively keep most gram positive and gram negative bacteria and containment particles larger than 0.1 µm from flowing through the membrane into the interior of the perforated core. The membrane can be one such as a polysufone sold by Memtec America Corp. under the trade name Filtrite®. For cores formed from carbon or ceramic material, the microporous membrane potentially can be eliminated if the effective size of the pores or perforations inherently formed in the carbon and/or ceramic cores are less than 0.45 µm.
A fibrous yarn 18 is wrapped in a close, tight spiral winding over the microporous membrane 17 along the length of the underlying perforated core to form a first spiral wound layer 18. The yarn typically is formed from spun 3dpf, 5,08 cm (2") fibers of polypropylene, cellulose acetate, rayon, lyocell, acrylic, polyester or any other fibrous material that will support the antimicrobial agent. For some applications, the yarn further can be formed from nylon, cotton, or a fibrillated filament yarn material. In addition, a yarn made from combinations of these polymers can be used to form the primary spiral wound yarn layer. The yarn is impregnated with an antimicrobial agent which is mixed with the yarn during formation of the fibers so that it is dispersed throughout the yarn fibers and will diffuse to the surface of the fibers during use of the filter cartridge.
The yarn used in the filter cartridge of the present invention can be between 10/1 c.c. to 0.3/1 c.c., preferably between 3/1 c.c. to 0.4/1 c.c. The yarn further can be made from fibers such as polypropylene, acrylic, cellulose acetate, nylon, polyester rayon, lyocell, cotton or combinations and blends thereof. The deniers of these fibers can be between 0.3 dpf to 10 dpf, the preferable range based on cost and performance being 1.5 dpf to 6 dpf. These fibers typically are rendered antimicrobial, either by treating them topically or by impregnating them with antimicrobial agent during their extrusion. The concentration of the antimicrobial agent in the fibers generally is between 100 to 10,000 ppm, preferably between 2000 ppm to 8000 ppm. The antimicrobial content of the final filter cartridge based on the yarn content should be between 100 ppm to 10,000 ppm, preferably between 2500 ppm to 7500 ppm.
Preferably, the antimicrobial agent is practically insoluble in the water passing through and over the filter cartridge, and is safe, non-toxic, non-carcinogenic, non-sensitizing to human and animal skin and does not accumulate in the human body when ingested. Generally, the antimicrobial is a broad spectrum antimicrobial agent, i.e., it is equally effective against the majority of harmful bacteria encountered in water. For example, an antimicrobial agent such as 2,4,4'-trichloro-2'-hydroxy diphenol ether, or 5-chloro-2phenol (2,4-dichlorophenoxy) commonly sold under the trademark MICROBAN®B, by Microban Products Co. generally is used. However, it will be understood various other antimicrobial agents can be used in the present invention.
The yarn 18 is wrapped in a single tight spiral wrapping or winding layer 19, wrapped so that there is no space between each of the individual turns or layers and so that there are no spaces between the first spiral wrapping or winding 19 and the microporous membrane 17.
After the first wrapping layer 19 has been applied, the same strand of antimicrobial impregnated yarn 18 can be used to wrap the filter cartridge in standard criss-cross or diamond-shaped wrapping wound in a standard pattern to form a first criss-cross wrapping layer 21. The criss-cross wrapping layer 21 does not have to be impregnated with the same antimicrobial agent impregnated yarn and can be made from non-antimicrobial impregnated yarn. Additionally, the criss-cross wrapping layer can be applied directly over the membrane without the spiral wrapping layer of yarn being applied.
The thickness of the criss-cross wrapping layer will determine the thickness of the filter cartridge. Preferably the criss-cross wrapping layer is approximately 0,635 cm (1/4") thick, although the total thickness of the criss-cross wrapping layer 21 can be of greater or lesser thicknesses, depending on the size of the filtration system housing in which the filter cartridge is to be installed, so as to enable the filter cartridge to fit tightly into a housing of a filtration system. Once the filter has been wrapped to the desired finished thickness, the yarn is cut and the end is tucked under or otherwise secured to a previous strand to prevent the yarn from unraveling.
In an additional embodiment, shown in Fig. 2 and 3, the first criss-cross wrapping layer 21 can be wrapped with a second microporous membrane 22, a second spiral wrapping layer 24, and a second section of criss-cross wrapping 26 wound in a standard pattern. In this way, greater filtration ability is provided and if one of the microporous membranes is punctured or otherwise made permeable to particles under 0.45 µm in size, the other membrane will act to trap and remove such particles.
As shown in Fig. 4, the antimicrobial membranes 17 and 22 overlap the ends 13 and 14 of the core. End caps 27 and 28 are applied over the open ends 13 and 14 of the core and the cartridge filter to seal the ends of the filter cartridges. The end caps 27 and 28, generally comprise a polyvinyl chloride (PVC) plastisol material containing an antimicrobial agent such as MICROBAN®B. The plastisol is poured in a liquid form into a shallow mold having an opened inside tube. A first end of the filter cartridge 10 is then set into the mold containing the plastisol liquid heated to a recommended temperature, for example 126,6 °C (260°F), for approximately seven minutes or until the plastisol has sufficiently permeated the yarn at the ends of the filter. The filter cartridge is removed and its opposite or second end is dipped into the plastisol liquid. The plastisol liquid is allowed to cool and solidify over the ends of the filter cartridge, whereupon the plastisol adheres to the fibrous yarn and to the protruding edges of the microporous membrane to seal the edges of the yarn and membrane at the ends of the filter cartridge, while still leaving the center of the cartridge open as shown in Fig. 5.
In an alternative embodiment, preformed end caps may be used in place of the end caps formed from the plastisol liquid to form the end caps. Such preformed caps generally are formed from a plastic material; such as polypropylene or similar material, treated with an antimicrobial agent. The caps are formed to ensure sealing of the ends of the microporous membrane and applied to the ends of the filter cartridge, preferably with an antimicrobial adhesive.
The end caps seal and cover the ends of the microporous membrane spiral wrapping yarn layer and criss-cross wrapping layer of the filter cartridge of each end thereof. This forces the water or other fluid being filtered through the filtration system to pass through the sides of the filter cartridge to ensure that the water or other fluid will pass through and contact the antimicrobial yarn of the criss-cross and spiral wrapping layers of yarn about the filter and through the microporous membrane so that contaminants of at least 0,1 µm or larger are trapped and removed from the flow of water passing through the filter cartridge, and the bacteria and other microorganisms therein will be eliminated by contact with the antimicrobial surfaces of the yarn layers to substantially clean the water flow of bacteria and other contaminants.
Additionally, if the water flow through the filter cartridge is to be reversed, flowing from inside of the cartridge out the sides thereof, the layering of the antimicrobial yarn/nonwoven material and the microporous membrane over the core is reversed. Thus, the core first is wrapped with the antimicrobial yarn/nonwoven mat, then overlaid with the microporous membrane. As a result, the water first will contact the antimicrobial yarn, to kill bacteria therein and thereafter contacts the microporous membrane, which traps and removes contaminant particles from the water flow. With such a construction, the filter cartridge of the present invention still provides a substantial cleaning of the water flow passing therethrough without a significant reduction in the amount of contaminants and bacteria removed from the water flow.

OPERATION

In use, the filter cartridge 10 typically is mounted within the housing of a conventional water filtration system such as an undersink system 30 as shown in Fig. 6 or in a faucet mounted filtration system 31 as shown in Fig. 7. In the system of Fig. 8, the filter cartridge 10 is fitted snugly inside a filter cartridge housing 32 and the filtration system 30 is connected to a water source 35 at the inlet end 34 of the housing. The water is supplied to the filtration system at the desired flow rate and flows into the upstream or inlet end of the housing as indicated by arrows 36. The water flows through the filter cartridge and out of the housing, whereupon the filter cartridge traps and removes particulate contaminants and bacteria within the water flow to clean and purify the water flow before the water flow exits the housing 32 through an outlet port 37. An additional filter cartridge 32 housing can be mounted downstream from the housing 32 for further cleaning.
In the water filtration system 31 of Fig. 7, the faucet mounted filtration system includes a housing 37 through which is formed internal flow passages 38 and 39. An outlet port or spout 41 is formed at the base of the housing and communicates with the outlet flow passage 39. The housing is connected to a faucet 42 by connecting portion 43 which fits over the outlet end of the faucet and which channels a flow of water therethrough and into the housing. As Fig. 9 illustrates, as the water flows into the filtration system from the faucet 42, it is directed along inlet flow passages 38, as indicated by arrows 44, through the filter 10 and out through the outlet flow passage 39 through the outlet port 41 with the water having been substantially cleaned and purified by the filter cartridge.
In the use of the filter cartridge 10 of the present invention in both of the filtration systems discussed above, the flow of water, indicated by arrows 36 (Fig. 6) and 38 (Fig. 7), is illustrated as passing through the sides of the filter cartridge and out the open ends of the core. It will, however, be understood by those skilled in the art that the filter cartridge of the present invention functions equally well if the water flow were to be reversed so as to flow in through the ends of the cartridge and out through the sides of the cartridge, without affecting the ability of the cartridge to trap and retard bacteria within the flow. Under the alternate flow conditions the sequence of membrane and antimicrobial yarn may have to be altered.

Claims

A bactericidal filter cartridge, comprising:

a core (12) formed from an activated carbon material and having an outer side surface and an inner side surface;

a microporous membrane (17) applied to said inner and outer side surfaces of said core (12);

a layer of antimicrobial yarn (18) spirally wound about said membrane (17) applied to said outer side surface of said core (12);

a layer of antimicrobial yarn (21) wound about said core (12) in a substantially criss-cross winding pattern having pores formed therethrough; and

end caps (27,28) applied at opposite ends of said core (12).
The bactericidal filter cartridge of claim 1 and wherein said microporous membranes (17) project over said opposite ends of said core (12) approximately 0,3175 cm (0.125 inches).
The bactericidal filter cartridge of claim 1 or 2 and said antimicrobial yarn (18,21) of said spiral wound and said criss-cross wound layers is formed from a polymer selected from the group consisting of nylon, polypropylene, cellulose acetate, rayon, lyocell, acrylic, polyester, polyethylene and combinations thereof.
The bactericidal filter cartridge of one of claims 1 to 3 and wherein said microporous membrane (17) includes nominal pores of approximately 0.1 to 5 µm.
The bactericidal filter cartridge of one of claims 1 to 4 and wherein the antimicrobial yarn comprises a fibrillated filament yarn.
The bactericidal filter cartridge of one of claims 1 to 5 and wherein the antimicrobial yarn comprises a fibrillated filament yarn is impregnated with an antimicrobial agent in a concentration of approximately 100 to 10,000 ppm.